Metering system



Feb.'20, 1940. J. OD. SHEPHERD 2,191,298

METERING SYSTEM Original Filed July 23, 1932 3 Sheets-Sheet l 1w swzrch zwdrd Coral INVENTOR Feb. 20, 1940. J QD SHEPHERD 2,191,298

I METERING SYSTEM Original Filed July 23, 1932 3 Sheets-Sheet 2 x fo - mvzhgga Feb. 20, 1940. Q'D SHEPHERD 2,191,298

METERING SYSTEM Original Filed July 23, 1932 3 Sheets-Sheet 3 f? #2 4 f? INVENTOR Patented Feb. 20, 1940 METERING SYSTEM Judson ODonald Shepherd, Atlanta, Ga.

Original application Ju 624,257. Divided and 1937, Serial No. 134,95

4 Claims.

This invention relates to measuring systems, and more particularly, to systems for measurin the time duration or the elapsed time of toll connections of a telephone system and for auto- 5 matically printing said elapsed time.

Heretofore, what is generally known as calculagraphs were used for timing such connections. The calculagraph was primarily a master clock operated independently of the telephone circuits. At the beginning or" acall the toll operator would insert a ticket in the clock and operate a lever. There would be printed on the ticket the dial of a clock with arrows indicating the time of day, a minute dial with an arrow indicating the minute and a five-minute dial with an arrow indicating the five-minute interval. At the termination of the call the operator would again insert the ticket in the clock and operate a lever. There would be printed on the dials other arrows from which the elapsed time and the charge could be computed.

The present invention provides an'electrical timing s stem associated with the toll switchboard. This system includes a motor or clock driven elapsed time meter for each cord circuit, control circuits for controlling the starting, stop-, ping and restoring to normal ofsaid meters, an electrically controlled printing mechanism for each switchboard position or for every two positions for printing the elapsed time, measured by any of said meters, signaling apparatus for indicating the condition of said meters and prin ing mechanism, and an operators key for each cord circuit for starting and stopping the corre sponding meter and for transmitting the reading of the meter (the elapsed time) to the printing mechanism which automatically prints the elapsed time on a ticket inserted therein. As disclosed, the Starting of the elapsed time meters, the printing of the elapsed time measured by the meters and the restoring to normal of the meters are under the control of the operator, and the stopping of the meters is controlled by theoperator or by the disconnect signal received by the op? ei'ator at the termination of a call.

The present application is a division of my copending application Serial No. 624,257, filed on July 1932, Patent No, 2,079,721, May ll, 1937.

Figures 1 and 2 of the drawings when-placed together in the mannerindicated in Fig. 6, show schematically the electrical circuits of the systern; Fig, 3 is a diagrammatic illustration of one side of the printing mechani *n; Fig. 4 is a diaamniotic illustration of the t t lng hanlsn'l with the-cover 5 is a 1y 23, 1932, Serial No.

this application April 5,

diagrammatic illustration of the selector bars and selector magnets of the printing mechanism; and Fig. 7 is a diagrammatic illustration of the driving means, and the start, stop and reset means associated with the fraction-minute wheel of one 5 of the time meters. The invention and the objects and features thereof, may be best understood by reference to the following detailed description of the operation of the system. Any necessary description of the apparatus will be set forth ,from time to time in connection with the description of the operation of the system.

When the toll switchboard operator ascertains from the calling party the details of the desired connection; she inserts answering plug 1 of atoll switchboard cord circuit 2 in jackl of a toll switching trunk 4. If the desired connection is of the type inwhich the calling party remains at his instrument and keeps his receiver off the hook, no current is impressed on the toll switching trunk and supervisory relay 5 remains unoperated. If the desired connection is of the callback? type, current is impressedon the toll stitching trunk when the receiver of the calling party is replaced on its hook, and relay 5 operates and causes supervisory lamp 6 to be lighted. The operation of relay'5 also closes the circuit or" the middle winding of stop relay 1 and causes the operation thereof. This circuit may be traced from the grounded battery :at relay 7, through the middle winding of said relay and lead 3 to the contact and grounded armature of relay 5. The operation of relay 1 at this time has no effect on the system because the operators control key ll is in its normal position. The operator now inserts plug It in jack H of the toll line leading to a distant central office with which the local circuit of the called party is associated, signals said distant central office and communicates the necessary information concerning the call to the distant central ofilce operator, who in turn completes the connection to the called party. When the called party answers, the operator at the central oiiice associated with the line of the calling party notifies said calling party that" the connection is'ready. Of course, if the connection is of the call back type, said operator rings the calling party and upon his response notifieshim that the connection is ready. The answer of the calling party,'in response to the ringing signal, removes battery from trunk 4 and causes the release of relay 5. Lamp 6 isextinguished, and relay 1 is released. The operator relay 1, to the then operates key 9 to the right to its start position. The operation of key 9 to this position prepares a locking circuit for relay 1, prepares a flashing circuit for lamp l2 which is associated with the printing mechanism, and closes the circuit of start relay l3. Said locking circuit for relay 1 may be traced from the grounded battery at key 9 through the middle right contact and spring of key 9, lead l4, lowerwinding of lower front contact of relay 1. Said flashing circuit for lamp l2 may be traced from grounded battery at said lamp, through lead 15, the upper right contact and spring of key 9 and lead is contact of relay 1. The circuit of start relay l3 may be traced from grounded battery at said said relay, lead l1,

relay, through the winding of e the lower right spring and contact of key 6, lead erating circuit for start magnet 2|.

, 18 and 19.

U may be traced from which was previously prepared by meter consists of a l8, and the lower back contact of relay 1 to the grounded lower armature of relay 1. The closure of the latter circuit causes the operation of start relay It. In operating, relay 13 opens at a second point, i. e., its upper back contact, the normally open flashing circuit of lamp is. At

its lower back contact said relay opens at a second point the normally open operating and locking circuits of cut-through relay 2i]. At its upper front contact said relay prepares an op- At itslower front contact said relay closes the operating circuit of wipe-out relay 22. The circuit of thewipeout relay may be traced from the grounded battery at said relay, through its upper winding, lead 23, and the lower armature of relay l3 to the grounded lower front contact of relay l3. Relay 22 in operating, closes-a locking circuit for itself through its upper winding, contact 12, armature 1|, armature. release circuit for itself from the grounded battery at said relay, through armature 11, contact 13, its lowerwinding, which is a differential winding, lead wo to the armature of relay 20. At contacts 14, 65 and 61 said relay opens at a second point the respective circuits of release magnet 24 and stepping magnets The functions and circuits of these magnets will be explained below. At contact 15 relay 22 prepares a flashing circuit for, lamp l9. At contact 10said relay closes the operating circuit of rotary magnet 2|, the. circuit of the operation IS. The operating circuit of magnet 2| the grounded battery of said magnet, through the winding of said magnet, lead 25,the upper front contact of relay l3, the upper middle armature of relay l3,lead 26, contact 10 of relay 22, to grounded armature 69 ofrelay 22. The operation of magnet 2| sets the elapsed time meter M into'operation. I

The elapsed time meter M, its driving means and the circuits associated therewith, are shown schematically in Figs. 2 and "I. 1 As shown, the driving shaft 21, a restoring shaft 28, a fraction-minute'dial wheel a minof relay =utedial wheel m, a ten-minute dial wheel t,

is adapted to be rotated periodically through a predetermined arc, for example of a revolution, by stepping magnet 18 which is operated to the upper front and the ground associated with said toration the fraction-minute wheel, the minute wheel and the ten-minute wheel rotate in the same direction as they do during the timing or the call. When the fraction-minute wheel, during the restoring operation, reaches its normal Zero position, stepping magnet 13 becomes operative to restore the minute wheel from any onnormal position to its normal zero position, and when it reaches its normal zero position, stepping magnet 19 becomes operative to restore the tenminute wheel from any off-normal position 'to its normal zero position. i Driving shaft 21 and restoring shaft 28 may be rotated 'bydifferent motors or by the same motor through suitable gearing apparatus. A driving disc 29 is mounted on driving shaft 21 and a restoring disc 89 is mount ed on restoring shaft 28. Fraction-minute wheel is mounted on a shaft iii, the axis of which is at right angles to the axes ofshafts 21 and 28. On one end of shaft BI is mounted by means of spring a disc 83, and on the other end is mounted by means of spring 34 a disc 85. As shown in Fig. I, the rotary magnet 21 is positioned between the face of disc83 and shaft 21, release magnet 24 is positioned between the face of disc 85 and shaft 28, and the faces of discs 83 and 85 are positioned adjacent the-periphery of discs 29 and 82, respectively. Whenrotary magnet 2i is operated, disc 83 is adapted to be moved into engagement with disc 29 and be rotated thereby at a constant predetermined speed. When release magnet 24 isoperated, disc 85 is adapted to be moved into engagement with disc and be rotated thereby at a greater speed. As'shown in Fig. 2, each of the wheels is divided into ten sections numbered from zero to '9. A group of five'brushes a to c, inclusive, is provided to press against each wheel at points in a straight line with respect tothe radius of each wheel. On each section of each wheel is embedded insulating material to form a different pattern according to a predetermined code. The pattern of the corresponding section of each of the wheels is thesarne. The uninsulated parts of each section of each wheel form a'conducting path. from brushes 0, to e, inclusive, to brush g which is grounded at 38. It can be seen therefore, that as the wheels rotate, certain brushes associated with each wheel will come in contact with the uninsulated portions of the sections and willbe connected to ground according to a predetermined code. For example, when the wheels are in their normal or zero position brush c of each wheel is connected to ground. Now suppose the connection described above should last 28.7 minutes.

Fraction-minute wheel 1 would be in such a position that the brushes would be in contact with section numbered 1 and brushes 0 and b would be connected to ground. Minute wheel m would be in such a position that the brushesassociated therewith would be in contact with section numbered 8 and brushes a, b and 0 would bev connected to ground. Ten-minute wheel t would be in such a position that the brushes associated therewith would be in con- Ten-minute wheel 73 is r releases.

tact with section numbered 2 and brush d would be connected to ground. It will be noted from an inspection of the drawing that that part of each wheel which is under brush e is not insulated in any of the sections except that numbered zero of which only one spot is insulated and that the brushes c will always be connected to ground except at the moment when the wheels are in their normal positions. This insures the operation of release magnet 24, stepping magnet 18 or Stepping magnet 19, as the case may be, when wipe-out relay 22 is released, no matter in what position, other than normal, any of the wheels are. The provision of an electrical carry-over arrangement in contradistinction to an ordinary mechanical carry-over arrangement is preferable in that it tends to insure more accurate registration. However, it is to be understood that the invention in its broader aspects is not limited to an electrical carry-over arrangement nor to the particular carry-over arrangement disclosed.

Returnin now to the operation of the system. it will be recalled that when the connection was ready, the operator operated key 9 to its start position. This caused the operation of relay 13 which in turn caused the operation of relay 22. The operation of relays l3 and 22 caused the operation of rotary magnet 2!. The operation of magnet 2i attracts disc 83 and causes it to move into engagement with rotating disc 29 and be rotated thereby at a constant predetermined speed. The rotation of disc 83 causes the rotation of fraction-minute wheel I at a constant predetermined speed. Vvhen the fraction-minute wheel has rotated 24 seconds or through it; of a revolution it is in such position that its brushes are in contact with the section numbered 5 and brush a is connected to ground. This completes the circuit for and causes the operation of stepping magnet 13. This circuit may be traced from grounded battery through the winding of said magnet, brush a and brush 9, to ground so. The operation of magnet it causes the pawl associated with its armature to engage the next tooth of minute wheel in. Magnet I8 remains operated as the fraction-n'iinute wheel rotates for the next 36 seconds or through the next of its revolution. As the fraction-minute wheel rotates from a position suchv that its brushes are in contact with the section numbered 9 to a position such that its brushes are again in contact with the section numbered 0, the connection between brush a and grounded brush 9 is broken and magnet 18 The release of magnet l8 steps minute wheel of a revolution. When the fraction-minute wheel has rotated 4 revolutions minute wheel m is in such position that its brushes are in. contact with the section numbered 4, and a circuit is completed for the operation of stepping magnet it. This circuit may be traced from grounded battery through the winding of said magnet and brushes a and g of minute wheel m to ground The operation of magnet it causes the pawl associated with its armature to engage he next tooth of ten-minute wheel t. Magnet i5 remains operated until minute wheel :02 rotates from a position such that its brushes are in contact with the section numbered 9 to a position such that the brushes are again in contact with the section numbered 6, at which time the connection between brush a and grounded brush g of minute wheel m is broken and magnet 79 is released. The release of magnet i9 steps ten-minute wheel 15 {6 of a revolu- 3 tion. The measuring wheels of the meter m continue to rotate as described above, as long as the connection remains established.

The method of carryover precludes errors in readings taken at or near the instant of this occurrence. As will be described below, the transmissionof the digit 9 is effected by brushes (1 and c of wheel J, for example, having ground extended to them from grounded brush 9 and the segments of the wheel, and digit by a circuit through brush 0 alone. As wheel f moves from position 9 to position 0, it effects the advanes 01 wheel m by one position, say from O to 1, by the opening of the circuit through brush a. It will be seen, therefore, that carryover is effected by the same means which causes the code of the lower wheel to be changed from 9 to 0, which prevents wheel for example, advancing to the position for transmitting digit 1 before wheel 7 reaches the position for transmitting 0, or wheel J reaching the position for transmission 0 before Wheel m reaches the position for the digit 1. The very change in code from 9 to 0, itself, effects the carryover which prevents an improper reading taken at or near the position in which carryover occurs, whereas mechanical carryovers may result in such readings being improper due to the next higher wheel changing. the circuit com iination through its brushes slightly ahead or behind the change effected by the lower wheel through its brushes.

At the termination of the call the restoration of the receiver to the hook by the calling party causes the operation of relay 5, or, the signaling of the local operator by the distant operator causes the operation of relay 3!, whichever occurs first. As described above, the operation of relay causes lamp: 8 to be lighted and causes the operation of stop relay l through its middle winding. Relay 3| may be an alternating current relay or a chain of relays adapted to be operated by alternating current. If the signal from the distant operator should be received before the calling party restores his receiver to its hook, relay 31 will be operated which will cause supervisory lamp 32 to be lighted and cause stop relay 7 to be operated through its upper winding. The latter circuit may be traced from the grounded battery at relay 7, through its upper winding, lead33, to the contact and grounded armature of relay 3|. The operation of stop relay opens at its lower back contact the circuit of start relay i3, which was traced above. At its lower front contact relay 1 closes a locking circuit for itself through the circuit which was prepared by the operation of key 9 to its start position and which was described above. At its upper front contact relay 7 closes the flashing circuit of lamp ii. The flashing of this lamp is caused by the operation of interrupter 34 which intermittently removes ground from the circuit. The release of relay [3 opens at its upper front contact the circuit of rotary magnet 2|, the release of which permits disc 83 to return under the influence of spring 82 to its normal disengaged position with respect to disc 29. This, of course, stops the operation of the meter. At its lower front contact relay l3 opens the operating winding of relay 22, but said relay remains operated through its locking circuit. At its lower back contact relay l3 prepares an operating and locking circuit for cut-through relay 29. At its upper back contact relay i3 closes the flashingcircuit of lamp l9. The latter circuit may be traced from grounded battery at lamp l9, through said lamp, lead 35, the upper back contact of relay I3, the uppermost armature of said relay, lead 36, contact l of relay 22, armature 16 of said relay, to interrupter 31 and ground. It will be noted that the circuit of lamp I2 is under the control of key 9 and stop relay 1, whereas the circuit of lamp I9 is under the control of start relay l3 and wipe-out relay 22. As a result lamp l2 starts flashing as soon as stop relay 1 is operated due to the restoration of the receiver at the calling subscribers station or to the reception of the disconnect signal from the distant central office. This indicates that the call has been terminated. A moment later lamp l9 starts flashing due to the release of start relay [3 and of rotary magnet 2|. This indicates that the timing apparatus has ceased to rotate, that the talking connections may be taken down, that the operators key 9 may be restored to normal or operated to strike position, and that the elapsed time now registered by the meter may be transmitted to the printing apparatus which is adapted to print said elapsed time on a ticket inserted therein.

The operator now takes down the connection by removing plugs l and Ill from jacks 3 and II, respectively, which causes supervisory lamps 6 and/or 32 to'be extinguished and the circuits of the upper and middle windings of stop relay 1 to be opened. Then the operator restores key 9 to its normal position. The restoration of key 9 to its normal position opens at its upper right contact and spring the flashing circuit of lamp l2, opens at the middle contact and spring the pocking circuit of stop relay 1, and opens at a second point the operating circuit of start relay l3. Lamp I9 continues to flash, which indicates that there is an elapsed time reading on one of the meters awaiting transmission to the printing apparatus. The release of stop relay 1 opens at a second point its locking circuit and the flashing circuit of lamp l2 and also prepares a circuit for the reoperation of start relay [3 when the cord circuit is used for establishing another talking connection. It is apparent from the drawings that, as described above, the cord circuit may be taken down before the restoration of key 9 to its normal position, or that it may remain up until after the key has been restored to normal, or even until after the key has been operated to the strike position and the reading printed on a ticket inserted in the printing apparatus.

The operator next inserts the ticket in slot 54 of the printing mechanism (Fig. 3) and operates key 9 (Fig. 1) to its strike position which causes the operation of cut-through relay 20. This circuit may be traced from grounded battery at the left of key 9, through the left upper spring and contact of key 9, lead 38, lower winding of relay 20, lower back contact of relay l3, middle armature of relay I3, lead 26, contact Ill of relay 22, armature (59 of relay 22, to ground. Uponoperating, relay 20 immediately closes a locking circuit for itself which may be traced from grounded battery at saidrelay, through the upper winding of said relay, the lowermost front contact and thelowermost armature of said relay, the lower front contact of relay l3, and through lead 26 to ground at relay 22. Cut-through relay 26 is of the gang type and is adapted to connect through its contacts and armatures leads 0. to dt, inclusive, with leads'afl to citl, respectively, and also to connect control leads sir and we with leads sin and 1001, respectively. In other words, the operation of relay 20 connects ground to certain of the conductors an to dt inclusive, dependingupon the positions of wheels I, m and t, which determine which of brushes a to d are connected to ground 30. In the illustration given above the elapsed time registered by meter M was supposed to be 28.7 minutes. In this case leads an, on, ami, bmi, cm1 and clti would be connected to ground. I

The essential features of the printing mechanism are shown schematically in Figs. 3, 4 and. 5, and the electrical circuits therefor are shown schematically in the upper part of Fig. l. The printing mechanism includesthree groups of four selector magnets, three groups of four selector bars and three groups of ten spring pins. One group of selector magnets, selector bars and spring pins is provided for each dial wheel of the elapsed time meternamely, the fractionminute wheel, the minute wheel, and the tenminute wheel. The four selector magnets and the four selector bars of each group correspond to brushes (1 to d, respectively, which are associated with each of the dial wheels. The ten spring pins of each group correspond to numerals zero to 9. Each selector bar is connected to the armature or" a selector magnet and is adapted to be shifted tothe left, for example, when the corresponding selector magnet is energized. The arrangement of the selector bars and magnets is shown schematically in Figs. 3 and 5, only those corresponding to the fraction-minute wheel being shown. The selector magnets are designated by reference characters afz to dfz, inclusive, and the selector bars are designated by reference characters (Us to (ifs, inclusive. As shown in Fig. 5,

each selector bar has a plurality of holes therein,

the relative position of each hole being in accordance with a predetermined code which corresponds to the code in the meter. Each group of spring pins 42f, 42m and 42t (Fig. 4) is carried by and inserted through a light frame Mr, Mm and ilt. Each frame forms a part of armature 4| of positioning magnet 40. Associated with each pin and located between the frame and a stop memher on each pin is a spring 63:, 43m and 43t, the function of which will be explained later. The printing mechanism also includes a register magnet 44 having a pivoted armature 45, three register bars 45:, 46m and Mr, and three type wheels comprising the printing wheels 411, 41m and 4h, visual wheels 48f, 43m and 4Bt, and pinion wheels 49f, 49m and Mt. The arrangement of the register magnet, the register bars and the type wheels, is shown schematically in Figs. 3 and 4. Each register bar, one for each digit, is pivoted at one end and is supported thereat, when the register magnet is unoperated, by supporting bars 50f, 50m and title, which form parts of armature 45. The other end of each register bar terminates in a rack 5! which engages pinion wheels 49:, 49m and 39e, respectively. Each register bar has a series of stops on its under side, these stops being carefully designed as to relative height in view or" the turning radius of the bars and pinion wheel. There is a stop corresponding to each of the ten spring pins. For a given number to be printed the selector magnets and the positioning magnet operate to cause the proper pin to be projected through the selector bars. When the register magnet operates and causes the register bars to be forced down, said bars encounter the projecting pins and are stopped. The movement of the register bars positions, by means of the racks and pinion wheels, the type wheels for the numerals to be printed. After the type wheels have been positioned a strike magnet 52 is energized causing the hammers associated with its armature 53 to strike a ticket which has been inserted in the slot indicated at 54 in Fig. 3. The impact forces the ticket against an inked ribbon 55 and the numerals on the printing wheels positioned in front of it,.and causes the numerals to be printed on said ticket. The insertion of the ticket in the slot breaks a circuit between spring 56 and the grounded back of the slot. The function of this feature will be described later. The numerals on the printing wheels and on the visual wheels are so positioned with respect to one another that for each given type number positioned in front of the hammers, the corresponding numeral on the visual wheel is disclosed to the operator through a window in the top of the printing mechanism, said window being indicated at 51 in Fig. 3.

The electrical and. mechanical operation of the printing mechanism will now be described with reference to the illustration given above in which 28.7 minutes was assumed to be the reading recorded on the elapsed time meter M. It will be recalled that the operator had operated key 9 to the strike position which in turn had caused the operation of cut-through relay 20, and that the operation of relay 2D had connected ground 35 to leads an, bf1, ami, bml, cm1 and (i151 and had connected grounded battery to leads sin and @001. The connection of ground to lead afi oompletes the operating circuit of selector magnet M2. The operation of selector magnet oh by means of its armature slides selector bar (Zfs to the left. Likewise, selector magnet bfz will be operated over grounded lead M1 and will slide selector bar bfs to the left. An inspection of Fig. 5 will indicate that with these bars in their operated positions and the other bars in their normal positions, the holes in all the selector bars will be in alignment opposite the arrow numbered 1 which corresponds to the position of spring pin numbered l, and that no other holes will be in alignment opposite any of the arrows. The connection of ground to leads 117m, 191m and 01m operates selector magnets amz, 221122 and cmz. The m2 magnets and the t2 magnets are not shown in the drawings. However, it is understood that these magnets are located behind the fa magnets and occupy the same relative positions as said is magnets. The same is true of the m3 and t3 selector bars. Consequently, an inspection of Fig. 5 will indicate that when selector bars ama, bma and 07723 have been shifted to the left, the other remaining in its normal position, the holes of all the ms selector bars will be in alignment opposite the arrow or spring pin numbered 8 and that no other holes will be in alignment opposite any of the other arrows or spring pins. The connection of ground to lead dti operates selector magnet dtz, the operation of which in turn causes selector bar dz: to be shifted to the left. An inspection of Fig. 5 will indicate that when bar dis has been shifted to the left, the others remaining in their normal positions, the holes in all the t3 selector bars will be in alignment opposite the arrow orpin numbered 2 and that no other holes will be in alignment opposite any of the other arrows or pins. The connection of grounded battery to lead stm energizes relay 39 (Fig. 1). The circuit of relay 3% maybe traced from grounded battery connected to lead str (Fig. 2), through lead str, the armature and contact of relay 20, lead sin and the winding of relay 39 to ground at said relay. The winding of relay 58 is connected in parallel with the winding of relay 39. However, relay 58 does not operate due to the fact that the operator inserted a ticket in slot 54 before operating key 9 to its strike position, said insertion breaking the connection between spring 56 (Figs. 1 and 3) and the back of the slot which is grounded at 59 (Fig. 1). Relay 38 is of the slow operating type and does not operate until after the selector magnets have been operated and the selector bars shifted to their left operated position. After the selector bars have been shifted to the left, relay 39 operates and closes the operating circuit of positioning magnet 40 (Figs. 1 and 4). This circuit may be traced from ground at relay 39 (Fig. 1), through the contact and armature of relay 39 and the winding of positioning magnet it to grounded battery.

Magnet M in operating attracts its armature (Fig. l) to the position shown., The movement of armature M to the position shown causes frames 4h, Mm and Mt to press against all of the springs 53x, 53m and 53s, and all of the pinsdflf, 42m and Mt of each group try to pass through the holes of the selector bars. However, it will be remembered that in the example given only the holes oppositethe f spring pin numbered 7, the holes opposite the m spring pin numbered 8 and the holes opposite the t spring pin numbered 2 are in alignment. As a result only these three pins will be able to pass through the selector bars. The springs 63f, 43m and 43s associated with the other pins are compressed by the movement of the frames and thus cause said other pins to press against said selector bars and at the same time permit the movement of the frames. The springs associated with the pins that pass through the bars are not compressed by the movement of the frames, but said springs transmit to the pins the force exerted by the movement of the frames in order to cause said pins to pass through the aligned holes in the selector bars. Fig. 4 shows the position of the pins in the example given. after the operation of the positioning magnet. Magnet 40 in addition to positioning the pins also closes the operating circuit of register magnet 44 (Figs. 1, 3 and 4). This circuit may be traced from the grounded armature of magnet 40 (Fig. 1), through the contact of said magnet and the Winding of register magnet 44 to grounded battery.

Magnet 44 in operating, attracts its armature 45. The movement of armature 45 lowers the supporting members 50f, 50m and 50 and by means of springs 60 forces down register bars 46f, 46m and 461; until they strike the pins protruding through the selector bars. The .lowering of supporting bars 58;, 50m and 5% also moves springs 6! into slots 52 or 63, depending upon whether the corresponding-selector bar has been shifted to the left or not. The movement of these springs into the slots locks the selector bars and prevents their derangement during the printing operation. As the register bars move downward until they strike the protruding pins, racks 5| rotate pinion wheels 49f, 49m and 49s through an are determined by the arc through which the corresponding register bar moves. In the example given the printing wheels 41r, 41m and 411; would be rotated to positions in which the numeral 7 of the wheel, the numeral 8 of the m wheel, and the numeral 2 of the t wheel would be opposite the respective hammers. With the printing Wheels in this position the reading 28.7 on the visual wheels would also be visible through the aperture 51 as described above. In addition to positioning the type wheels the operation of regnet 52 operates and causes ister magnet 44 also closes the operating circuit of strike magnet 52 (Figs. 1 and 3). This circuit may be traced from the grounded armature and contact of magnet 44 (Fig. 1), through the winding of magnet 52 and the lower back contact and armature of relay 58, to grounded battery. Magthe hammers associated with its armature 53 to strike the ticket and force it against ribbon 55 and the numerals on the printing wheel. 7 This causes the reading to be printed on the ticket, said reading being 28.7 in the example given. This completes the printing operation. I i

In addition to can 'ng the operation of strike magnet 52, the'operation of register magnet 44 closes the circuit of the lower winding of wipeout relay 22. This circuit may be traced from the grounded armature and contact of magnet 44 (Figs, 1 and 2), the upper back contact and armature of relay 58, lead 1001, the contact and armature of relay 20, lead wo, the lower winding of relay 22, contact 13 and armature T1 of relay 22, to grounded battery at said relay. Relay 22, being differentially wound, releases. The release of relay 22 opens at contact 12 its own locking circuit, opens at contact 10 the operating and the locking circuit of relay 20, opens at contact 75 the flashing circuit of, lamp l9, closes at contact 14 the operating circuit of release magnet 24 in case the fraction-minute wheel a of the elapsed time meter is inan off-normal position, closes at contact theoperating circuit of stepping magnet !8 in case the minute wheel m is in an offnormal position, and closes at contact 6"! the operating circuit of stepping magnet 19 in case the ten-minute wheel 15 is in an off-normal position. The release of relay 2!] removes grounded battery from lead strl which causes the release of relay 39. The release of relay 39 causes the release of the magnets of the printing mechanism which restores all said printing mechanism to normal except the selectorbars. The release of relay 2% also removes ground from leads ah to dti, inclusive, which releases any of selector magnets afz to d132, inclusive, which may be operated. The release of the latter magnets restores the selector bars to normal. The operation of release magnet 24 and/or stepping magnet 18 and/or stepping magnet 19 restores the wheels of the elapsed time meter to their normal zero position. The extinguishment of lamp it indicates to the operator that the printing mechanism has been restored to normal and that said apparatus may be used again for another connection. After the extinguishment of lamp 59 the operator then, of course,

operates key 9 from its strike position to its normal position. v

The restoring operation of the meter will be described with reference to the example given above. It will be recalled that under said example the section numbered 7 of the fractionminute wheel, the section numbered 8 of the minute wheel, and the section numbered 2 of the ten minute wheel were under the respective groups of brushes when key 9 was operated to stop the timing of the call. With the fraction-minute wheel in this position brushes a and e thereof will be connected to ground 30 through brush g thereof and, as a result, the circuit of release magnet 24 will be prepared, the-circuit of stepping magnet 18 will be closed, and stepping magnet 18 will be operated. With the minute wheel in this position brushes a and e thereof will be connected to ground 30 through brush g thereof and, as a result, the circuit of'stepping magnet 19 will be magnet 18 closed, magnet 19 will be operated, and the stepping circuit of magnet 18 will be prepared. With the ten-minute wheel in this position brush e thereof will be connected to ground through brush 9 thereof and the stepping-circuit of magnet 19 will be prepared. Now, when relay 22 is released as described above, its release will have no immediate effect on stepping magnets 18 and 19 and as a result the minute wheel m and the ten-minute wheel t will remain stationary for the time being, but the release of relay 22 will cause the immediate operation of magnet 24. The operation of magnet 24 attracts disc 85 and causes it to move into engagement with disc and be rotated thereby at acomparatively high speed. This causes the fraction-minute wheel to be rotated until its section numbered 9 passes out from under the brushes associated with said wheel, at which time ground is removed from release magnet 24 and stepping magnet 18. The release of magnet 24 permits disc to return under the influence of spring 84 to its normal disengaged position with respect to disc 80 and the rotation of fraction-minute wheel I ceases, it now being in its normal zero position. The release of stepping steps minute wheel m of a revolution by means of the pawl associated with its armature. When the armature of magnet 18 reaches its full released position, it closes at contact 88 a stepping circu't for said magnet. This circuit may be traced from grounded battery through the winding of said magnet, the armature of said magnet, contact 88, armature 6G and contact 65 of relay 22 and brushes e and g of the minute wheel, which is in an ofi-normal position, to ground 30. Magnet 18 operates and releases repeatedly, and, as a result, steps minute wheel m around until section numbered 9 thereof passes out from under the brushes associated with said wheel, at which time ground is removed from brushes wand e thereof. The removal of ground from brush e prevents the further operation of stepping magnet 18 and hence, minute wheel m stops rotating and remains in its normal zero position. The removal of ground from brush a releases stepping magnet 19. The release of this magnet steps ten-minute wheel t of a revolution. The full release of the armature of magnet 19 closes a stepping circuit for said magnet. This circuit may be traced from grounded battery through the winding of said magnet, the armature of said magnet, contact 89, armature 68 and contact 61 of relay 22, and brushes e and g of ten-minute wheel t to ground 30. Magnet 19 operates and then releases repleatedly, and, as a result, steps ten-minute wheel t around until section numbered 9 thereof passes out from under the brushes associated with said wheel, at which time ground is removed from brush e. The removal of ground from .brush e prevents the further operation of stepping magnet I9 and hence. ten-minute wheel 15 stops rotating and remains in its normal zero position. All three wheels have now been restored to their normal zero positions. Of course, it is understood that the stepping magnets operate very rapidly and that the entire restoring operation of the three wheels takes place in a very short time.

The restoring operation of the wheels from any oil-normal position is identical with that described above, except where either or both of wheels 1 and m are in such position, when relay 22 is released, that the brushes thereof are in contact with any of the sections numbered 0 to 3,

1 is in such a position, stepbegin to operate as soon as relay 22 releases and will rotate the minute wheel until the brushes of the fraction-minute wheel come in contact with section numbered 4, whereupon said stepping magnet will operate and remain operated until the fraction-minute wheel is restored to its normal zero position. If minute wheel m is such a position, stepping magnet 19 will begin to operate as soon as relay 22 releases and will continue to operate until the brushes of minute wheel m come in contact with section numbered 4, whereupon said stepping magnet will operate and remain operated until the minute wheel is restored to its normal zero position. From this point on the restoring op eration is the same as that described above.

By referring to Fig. 7, it will be seen that stud 86 is fastened to disc 83. This stud is adapted to come in contact with stop pawl 81 when the fraction-minute wheel reaches its normal zero position during the restoring operation.

t will be apparent from an inspection of Fig. 7 that stud 85 will not engage pawl 87 during the timing of the call because disc 83 isattracted and moved to the right by magnet 2| when it is operated, but that said stud will engage said pawl during the restoring operation because at this time magnet 21 is unoperated and disc 83 is in its normal position. This additional stepping means is provided to insure that the fractionminute wheel stops in its normal zero position without any overthrow, which, if such means were not provided, might occur during the .restoring operation due to the comparatively high speed at which the fraction-minute wheel is restored.

As shown. the system is so arranged that the operator at any time during the connection may take a reading of the elapsed time without printing said elapsed time, and without restoring the elapsed time meter to normal. To do this the operator merely operates key 9 to the strike position, notes the reading indicated on the visual wheel of the printing mechanism, and then restores key 9 to the starting position. As the key passes through its normal position in its movement from its start to its strike position, start relay i3 is released. The release of relay I3 releases rotary magnet 21 which stops the rotation of the meter, prepares an operating and locking circuit for cut-through relay 25, and closes the flashing circuit of lamp is. The further movement of key 9 to its strike position causes the operation of cut-through relay 2! The operation of relay in the same manner as before, closes a locking circuit for itself, prepares a circuit for the release of relay 22, causes the operation of certain. selector magnets an to dig and causes the operation of relay 39, the latter in turn causing the operation of positioning magnet 4!! and register magnet M. As described above, the operation of these relays and magnets causes the type whee-ls of the printing mechanism to be rotated to such a position that certain numerals on the visual wheels corresponding to the elapsed time measured by the meter, are visible through the aperture indicated at 51, and the numerals on the printing wheels are positioned in front of the strike hammers. However, since no ticket is inserted in the slot indicated at 54, the circuit between spring 55 the grounded back of the slot will remain closed. Hence, the operation of relay causes the operation of ticket test relay 58. This circuit may be traced inclusive. If wheel ping magnet 18 will from the grounded back of the slot indicated at 59, through spring 56, the winding of relay 58, lead sin, the contact and armature of relay 20, and lead str to grounded battery. The operation of relay 58 prevents, after the operation of register magnet 44, the operation of strike magnet 52 by opening the circuit thereof at its lower contact and armature, and also prevents, after the operation or register magnet M, the release of wipe out relay 22 by opening, at a second point, circuit of the lower winding of diiferential relay Thus, the printing mechanism will inate the elapsed time, but in this case will not automatically restore the elapsed time meter and its own mechanism to normal. After the reading has been noted, the operator restores key 9 to its position. The restoration of said key to its rt position rec-perates start relay l3. The reation of start relay I3 reopens the flashing circuit of lamp is, reoperates the rotary magnet 25 to rest-art the rotation of the meter and release relay The release of relay 21 opens, at a third point, the circuit of the lower winding of differential relay 22, releases relay 58, releases relay which in turn releases magnets 40 and 44, and releases magnets (U2 to dtz. Thus, the reading of the elapsed time meter is made, the printing mechanism is restored to normal, and the meter resumes the timing of the call after only a momentary interruption.

Also, an auxiliary wipe-out key is provided to clear any meter after a false start. This key is indicated at 64 in Fig. l. The operation of this key, after key 9 has been operated to its strike position, closes the circuit of the lower winding of wipe-out differential relay 22, and causes the release of said relay. This circuit may be traced from the grounded contact and spring of key 64, through lead war, the contact and armature of relay 28, lead wo, the lower winding of relay 22, contact 13 and armature 11 of relay 22, to grounded battery. The release of this relay opens its own locking circuit, opens the circuit of lamp l5, opens the operating and locking circuits of relay 2%, and closes the circuit of release magnet 24 and/or the circuits of stepping magnets 78 and 79. The release of relay 20 and the operation of magnets 24, 18 and/or 19, restores all the apparatus to normal, as described above. The operator then, of course, releases key 64 and restores key 9 to the start position which starts anew the timing of the call.

This invention has been illustrated and described in connection with a system for timing telephone toll calls. However, it is to be understood that the apparatus and principles of opera tion disclosed are applicable to any type of measuring system in which it is desired to transmit electrically the reading of a meter or register to a printing and/or indicating mechanism, and to operate said mechanism electrically for the purpose of printing and/or indicating said reading. It is also to be miderstood that the meters per se or the respective sub-systems per se, in contradistinction to the disclosed system as a whole, may be used separately to accomplish the functions contemplated thereby without departing from the spirit and scope of the invention.

What is claimed is:

1. Measuring apparatus comprising a first counting unit, driving means therefor, circuit means for electrically transmitting the value of the readings 01 said counting unit to a distant station. said circuit means being variably conditioned for diflerent readings of the first counting unit, a second counting unit, control means associated with said first counting unit for varying the condition of said circuit means in accordance with the readings of the first counting unit, and means controlled by the production of a predetermined condition in the circuit means for operating said second counting unit.

2. Measuring apparatus comprising, in combination, a first counting unit, a second counting unit, circuit means for electrically transmitting the readings of said counting units, control means associated with and controlled by said counting units for varying the condition of said circuit means in accordance with the readings of said counting units, and means controlled by the control means associated with said first counting unit for operating said second counting unit, said last mentioned means being responsive to a predetermined condition in the circuit means associated With said first counting unit.

3. In combination, a measuring unit at a station, means to operate said measuring unit cyclically, a plurality of electrical circuits, means associated with said measuring unit to control said circuits to transmit the readings of said measuring unit to a distant station by characteristic codes of current conditions individual to said readings, the code corresponding to the last measurement in a cycle and the code corresponding to the first measurement in the next cycle being different by current change in at least one of said circuits, a second measuring unit at said first station, means to operate said second measuring unit in response to the above mentioned change in code at the end of a cycle of said first measuring unit.

4. A register comprising in combination, a plurality of measuring wheels, driving means adapted to rotate one of said wheels, control means adapted, when operated to one position, to cause the rotation of said wheel by said driving means and when operated to a second position, to stop said rotation, a stepping magnet adapted, when the first mentioned wheel rotates through each revolution, to cause the next succeeding wheel to rotate through a predetermined-arc, and restoring means adapted, when said control means is operated to its second position, to rotate said first mentioned wheel to the position it occupied prior to its rotation, the rotation of said wheel to said position being adapted to cause the stepping magnet to operate and release repeatedly and rotate said next succeeding wheel to its normal zero position.

JUDSON ODONALD SHEPHERD. 

